Pediatric cardiac interventions have advanced significantly, with balloon angioplasties and devices now used routinely to treat conditions like atrial septal defects, ventricular septal defects, and patent ductus arteriosus. Newer interventions still in clinical trials include muscular VSD and perimembranous VSD device closure, flow restrictor implantation as an alternative to pulmonary artery banding, and components of the Norwood procedure in the catheterization lab. While short term outcomes are encouraging for many procedures, long term data is still needed to fully evaluate safety and efficacy. Continued innovation holds promise for more pediatric heart conditions to be treated using minimally invasive techniques.
2. Theme Symposium
CARDIAC INTERVENTIONS IN PEDIATRIC CARDIOLOGY: THE FUTURE
Vikas Kohli
From the: Senior Consultant Pediatric Cardiology, Apollo Centre of Advance Pediatrics,
Indraprastha Apollo Hospitals, New Delhi-110044.
Correspondance to: Dr Vikas Kohli, Apollo Centre of Advance Pediatrics,
Indraprastha Apollo Hospitals, New Delhi-110044.
Email: vkohli_md@yahoo.com
Pediatric Cardiac interventions have come a long way from the initial intervention in the 1950's. Balloon angioplasty
has been accepted as the procedure of choice in several congenital anomalies. Apart from balloon angioplasties/
valvuloplasties, Atrial Septal Defect, Ventricular Septal Defect (muscular) device closure have been FDA approved
with adequate world wide clinical experience and long-term follow-up. In addition, newer procedures are under
clinical trial for perimembranous VSD device closure in the catheterization lab; per operative closed heart procedure
in the operation theatre or as a hybrid procedure. Palliative procedures like flow restriction to lungs with devices to
equate with surgical pulmonary artery banding; stenting of the patent ductus arteriosus in duct dependent cyanotic
heart disease in the newborn or a combination of these form transcatheter Norwood stage I in the cath lab.
Experience and technology will also help make transcatheter Fontan operation possible and that does not seem too
far. The emphasis in pediatric cardiac interventions shall always remain that the decision, procedure, and
management of their complications is a joint effort of the surgeon and the interventionalist.
Key words: Pediatric, Cardiology, Stent, Interventions, PDA, ASD, VSD.
Subsequently the Clamshell device (11F sheath), Sideris
button device (8F), Cardioseal (11F), Angelwings (11F) and
the ASD Occluder System device (10F) also require large
delivery sheaths. The major development in this field has been
the ability to deliver the repositionable, retractable Amplatzer
IT WAS the pioneering work of Rubio-Alverez in 1950’s that
initiated pediatric cardiac interventions. Interventional
Pediatric Cardiology since then has come a long way and
several lesions are now primarily treated by interventional
catheterization. These include pulmonary valve stenosis,
aortic stenosis, patent ductus arteriosus, aortic recoarctation.
In other situations, interventions are used preferably over
surgery including native coarctation of aorta, stenting for
branch pulmonary arteries, pulmonary valve balloon
dilatation in tetralogy of Fallot’s, re-dilatation of the stenosed
conduit placed in the right ventricular outflow tract, stenosed
Blalock-Taussig shunt and coil embolization of collateral
vessels. In the last decade, the spectrum of interventions have
increased to an extent that surgical procedures are being
replaced by interventional procedures, making pediatric
cardiology one of the more advanced fields in medicine and
further increasing the challenges of pediatric cardiac surgery.
Table 1. Pediatric cardiac interventions currently in the
process of being incorporated into clinical
practice.
S.No.
Interventions
1.
2.
Vascular Plug implantation
5.
Norwood Stage I in Cath Lab (PDA stenting + Flow
Restrictor Implantation)
6.
Muscular VSD Device Closure (Clinical Trial complete)
7.
ASD Device (FDA approved)
8.
Ever since the pioneering transcatheter device closure of a
secundum atrial septal defect by King [1] in 1974 and the
subsequent work of Rashkind [2], cardiologists have been
trying to make interventional closure the preferred mode of
treatment. The first device used by King required a 23F sheath.
PDA stenting in Ductal dependent cyanotic CHD's
4.
ATRIAL SEPTAL DEFECT CLOSURE
Flow Restrictor Implantation
3.
We start with an established intervention i.e., ASD device
closure and discuss newer interventions which may be
incorporated into clinical practice in the next few years.
(Table 1).
Perimembranous VSD Device Closure (Phase 1
Clinical trial)
a. Transcatheter
b. Peroperative (beating heart surgery)
c. Hybrid Surgery
PDA Device (FDA Approved)
VSD = ventricular septal defect; CHD = congenital heart
disease; ASD = atrial septal defect; PDA = patent ducuts
arteriosus.
7
Apollo Medicine, Vol.1, September 2004
3. Theme Symposium
device through a sheath as small as the 6F or 7F. This
technological advancement took place due to the use of Nitinol
material for cardiac devices. After initial trials, the Amplatzer
device was approved for clinical use in the United States by the
FDA in 2002. The Amplatzer device for ASD closure is the one
most frequently used in clinical practice. The device has 3
parts connected to each other (Fig. 1): the left atrial disc is the
largest (about 14mm larger than the size of the ASD); the right
atrial disc is slightly smaller though still larger than the ASD.
The 2 discs are connected by the “waist” or the stent which is
the size of the ASD itself. Of the devices available presently,
the early closure rates at 3 months for this device (>98%) are
the highest. Incidence of severe complication for Amplatzer
device has been amongst the least (0.3 %). Modes of
retrieval of embolized device remain difficult though not
impossible.
the procedure[4]. This is done via a catheter; it requires at least
a 9F sheath and this maybe the limiting factor for its use in the
pediatric age group.
Outcomes–immediate, intermediate and late
The immediate safety of the procedure has been proven
with several thousand device closures which have been
performed. Closure rates were also shown to be very high with
majority studies showing complete closure of the ASD by 3
months. As more and more studies have shown better
outcomes, the focus is shifting to late and long-term effects of
non-surgical closure.
Recent reports of neurodevelopment assessment of
children who have had surgical closure of ASD compared to
device closure have shown interesting results. The patients
with surgical closure of ASD showed significantly lower
visual-spatial/visual-motor skills. This may be related to the
cardiopulmonary bypass [5].
Limitations of the Procedure
The procedure can be carried out only in select patients of
secumdum ASD with good rim margins. It is carried out under
general anesthesia mainly for purposes of the prolonged transesophageal echo (TEE) which needs to be performed during
the procedure.
VENTRICULAR SEPTAL DEFECT CLOSURE:
MUSCULAR
Muscular ventricular septal defects can be very
challenging to close surgically and several variations of the
surgical technique have been discussed in literature.
The limitation of device closure is that none of the present
devices currently are able to close ASD's with small rims. All
patients with large ASD’s, ASD’s with small rim and sinus
venosus and primum ASD’s have to undergo surgical closure.
There has been a recent trend towards use of intracardiac
echocardiography (ICE) for better anatomy delineation during
These include left ventriculotomy which may be
associated with an aneurysm or electrical problems in the
future [6].With this in mind the interventional closure of
muscular VSD has taken precedence over surgical closure and
now several techniques for closure of muscular VSD by device
have been developed and reported. These include peroperative closure of the VSD; the Hybrid technique for closure
of the VSD and beating heart closure of the VSD. These are in
addition to the now established and accepted transcatheter
non-surgical closure of the VSD. The device is in the process
of and nearing FDA approval in 2004.
The initial results of muscular VSD closure by Amplatzer
device which is clinically the most often used device for all
septal defects are encouraging. The devices have been
implanted in congenital, post-operative residual VSD, in postmyocardial infarction VSD and in post-traumatic VSD.
In the largest reported single study for muscular
VSD’s (MVSD) thirty-two patients underwent attempted
transcatheter closure of an MVSD. Of these 19 had congenital
unoperated MVSD, twelve had post-MI MVSD and 1 patient
had an acquired VSD post-surgical repair of hypertrophic
cardiomyopathy. The median age of patients was 11.5 years.
The device was implanted successfully in 30 patients. The
authors consluded that the Amplatzer MVSD occluder is a safe
and effective device for closure of MVSDs up to 14 mm in
diameter and further clinical trials with this device are
needed [7].
Fig. 1. The ASD device is seen held with the larger LA disc, the
connecting "stent" and the RA disc. LA = left atrium; RA =
right atrium
Apollo Medicine, Vol.1, September 2004
8
4. Theme Symposium
VSD DEVICE CLOSURE-PERIMEMBRANOUS VSD
Perimembranous VSD's are very close to and just below
the aortic valve. This makes the procedure of device closure
more challenging. The device has been designed in such a way
that its LV disc is eccentric without any rim towards the Aortic
valve. Initial results have been encouraging with the eccentric
Perimembranous VSD closure device. The long-term results
would decide the final outcome of whether this becomes a
standard procedure or not.
Percutaneous closure of perimembranous ventricular
septal defects (VSDs) has been feasible, safe, and effective
with the new eccentric Amplatzer membranous septal
occluder in a small number of patients [8,9]. Ten patients with
volume-overloaded left ventricles underwent closure under
general anesthesia and transesophageal guidance (TEE).
Implantation was successful in all patients. Nine patients
had complete occlusion within 1-3 months. Device-related
aortic or tricuspid insufficiency, arrhythmias, and
embolization were not observed. Two patients had slight
gradients across the left ventricular outflow tract, normalizing
after 3 months.
Fig. 2. The angiogram still frame shows bilateral flow restrictor
implantation in each branch pulmonary artery.
A new technique has been under trial for closure of
the defects under echocardiographic guidance without
cardiopulmonary bypass to prevent the deleterious effects of
bypass. In the study carried out on pigs with naturally
occurring perimembranous ventricular septal defects
underwent closure of the defect in the operating room by using
the perventricular technique. The device was deployed under
echocardiographic guidance with the heart beating. The
perventricular technique appears to be excellent for closure of
perimembranous ventricular septal defects in the operating
room. The technique might be feasible in smaller babies, who
are high-risk candidates for closure in the catheterization
laboratory. Cardiopulmonary bypass and prolonged hospital
stay are avoided [10]. This has subsequently been tried in
humans with good results though trial on large number of
patients is awaited.
Fig. 3a. The catheter course via right aortic arch to left subclavian
artery to (closed) ductus arteriosus is noted. The LPA
arises from the PDA as shown here.
FLOW RESTRICTOR IMPLANTATION AS AN
ALTERNATIVE TO PULMONARY ARTERY
BANDING
Pulmonary artery banding is used as a palliation prior to
muscular VSD closure or as part of other procedures like
Damus-Kaye-Stansel or Norwood Stage I. It may also be used
for reducing the pulmonary pressures in patients with high
flow Single Ventricle physiology. The inability to predict the
final PA pressure while banding the artery has resulted in
several alternative techniques being looked at including
externally adjustable bands. Flow restrictor implantation is
also an attempt at replacing a surgical palliative procedure
with a non-surgical interventional procedure. The procedure,
as per personal communications, has been tried on about 14
Fig. 3b. The PDA has been stented and the continuity of left
subclavian artery, PDA and LPA is noted. LPA = left
pulmonary artery; PDA = patent ducuts arteriosus;
9
Apollo Medicine, Vol.1, September 2004
5. Theme Symposium
Key Messages
• Pediatric Cardiac Interventions have advanced significantly in the last decade that, apart from balloon angioplasties, certain
other procedures have already been FDA approved and incorporated in clinical practice (ASD Device closure, PDA Device
Closure).
• Some other procedures are in the process of completion of clinical rials e.g. Muscular VSD device closure. Innovative
procedures like per-operative (beating heart) device closure, Hybrid technique.
• Several patients have safely undergone Perimembranous VSD closure in the catheterization lab with the Eccentric VSD
Device: long-term results will help in deciding the true safety of this procedure.
• Innovative procedures like PDA stenting in Duct dependent cyanotic congenital heart disease and Flow Restrictor implantation
in high flow situations are in the stage of clinical trials.
• Norwood Stage I (Flow Restrictor Implantation with PDA stenting) and Fontan Completion (with prior surgical preparation)
in catheterization lab are other interventions one can look forward to in the coming several years.
patients as part of Norwood Stage I (associated with PDA
stenting) and seven of these patients have gone on to have the
surgical stage II. The author has performed this procedure in 2
children (Fig. 2). The procedure involves inserting an ASD
like device within each branch pulmonary artery. The device
has 2 holes in the center which allow some flow and there by
restrict majority of the flow through it. The procedure is
referred to as flow restriction and the device as Flow
Restrictors. The diameter (outermost ) would be similar to that
of the branch pulmonary artery diameter and the axis of the
device has to be at 90 degrees to the long axis of the branch
pulmonary artery. This is able to generate enough gradient
within the branches to prepare them for single ventricle
palliation [11]. Figure 2 shows the angiographic picture of one
of the patients who has undergone this procedure by the author
and at 6 months follow-up has 70 mmHg gradient across the
flow restrictor.
diameter of 4-5 mm without procedural deaths. Overall
survival rate after 6 years was 86%. Corrective surgery was
possible in six patients.
In another large study, 69 patients with duct-dependent
pulmonary circulation underwent cardiac catheterization with
the intent of PDA stenting as first palliative procedure. Patent
ductus arteriosus stenting was successful in 51 patients
(91.1%) and failed in 5 patients (8.9%). There was no
procedure-related mortality. Patent ductus arteriosus stenting
proved to be an attractive alternative to surgical shunt in a
majority of patients with duct-dependent circulation. An
absolute contraindication to this technique is the presence of
branch pulmonary stenosis [13].
PDA DEVICE CLOSURE
This device intervention technique is being discussed
towards the end because it is the most evolved intervention
amongst device closure. The procedure has replaced surgical
ligation of PDA except in the smallest of babies (premature or
newborn babies). After the limitations of the Rashkind
Umbrella were realized that in the late 90’s the Amplatzer duct
occlude became available. The major advantages are that it can
be used to close PDA of all sizes via a small size sheath. The
closure rates are close to 98% instantaneously and 100% at
3 months. The complications if any reported are minor related
to access for arterial catheterization.
STENTING OF THE NEWBORN PDA IN DUCTAL
DEPENDENT CONDITIONS
Stenting of the newborn duct in ductal dependent
conditions has long been the objective of interventional
cardiologists. It has only been recently that this has become a
reality in the newborn period mainly due to the advancements
in the hardware available for arterial access in a newborn baby
and for delivering a premounted stent. Recent results have
shown this to be a safe intervention with good results [12].
Personal experience confirms the same for selected patients
with favourable duct anatomy. Figures 3a & 3 b show the duct
being stented in a patient with tetralogy of Fallot’s with right
aortic arch, left pulmonary artery from PDA which arose from
the left subclavian artery. With the duct closing, the flow to left
lung via left pulmonary artery was completely stopped. PDA
stenting restored this.
CONCLUSION
Pediatric cardiac interventions are a rapidly advancing
field with several new procedures replacing some of the
simpler surgeries (PDA ligation) or replacing some of the
palliative surgeries (Stenting of duct for BT shunt; Flow
restrictor implantation for PA banding; Norwood stage I in
catheterization lab). One can look forward to more
interventions getting established in the coming years
including transcatheter Fontan completion.
In one of the larger series, balloon-expandable stents were
implanted in 21 patients with ductal dependent cyanotic
congenital heart disease. The PDA was dilated to a final
Apollo Medicine, Vol.1, September 2004
10
6. Theme Symposium
REFERENCES
2. Rashkind WJ, Cuaso CE. Transcatheter closure of atrial
septal defects in children. Eur J Cardiol. 1977; 8: 119-20.
8. Pedra CA, Pedra SR, Esteves CA, Pontes SC Jr, Braga SL,
Arrieta SR, Santana MV, Fontes VF, Masura J. Percutaneous
closure of perimembranous ventricular septal defects with
the Amplatzer device: technical and morphological
considerations. Catheter Cardiovasc Interv. 2004 Mar; 61(3):
403-10
3. Berger F, Ewert P, Bjornstad PG, Dahnert I, Krings G, BrillaAustenat I, Vogel M, Lange PE. Transcatheter closure as
standard treatment for most interatrial defects: experience in
200 patients treated with the Amplatzer Septal Occluder.
Heart 1999 Sep; 82(3): 300-6.
9. Thanopoulos BD, Tsaousis GS, Karanasios E, Eleftherakis
NG, Paphitis C. Transcatheter closure of perimembranous
ventricular septal defects with the Amplatzer asymmetric
ventricular septal defect occluder: preliminary experience in
children. Heart. 2003 Aug; 89(8): 918-22.
4. Zanchetta M, Rigatelli G, Pedon L, Zennaro M, Carrozza A,
Onorato E,Maiolino P. Transcatheter atrial septal defect
closure assisted by intracardiacechocardiography: 3-year
follow-up. J Interv Cardiol. 2004 Apr; 17(2): 95-8.
10. Amin Z, Danford DA, Lof J, Duncan KF, Froemming S.
Intraoperative device closure of perimembranous ventricular
septal defects without cardiopulmonary bypass: preliminary
results with the perventricular technique. J Thorac Cardiovasc
Surg. 2004 Jan; 127(1): 234-41.
1. King TD, Mills NL. Nonoperative closure of atrial septal
defects. Surgery 1974; 75(3): 383-8.
5. Visconti KJ, Bichell DP, Jonas RA, Newburger JW, Bellinger
DC. Developmental outcome after surgical versus
interventional closure of secundum atrial septal defect in
children. Circulation 1999 Nov 9; 100(19 Suppl): 145-50.
11. Maher KO, Gidding SS, Baffa JM, Norwood WI Jr. New
developments in treatment of hypoplastic left heart syndrome.
Minerva Pediatr 2004; 56(1): 41-9.
6. Kitagawa T, Durham LA 3rd, Mosca RS, Bove EL. Techniques
and results in the management of multiple ventricular septal
defects. J Thorac Cardiovasc Surg. 1998 Apr; 115(4): 848-56.
12. Michel-Behnke I, Akintuerk H, Thul J, Bauer J, Hagel KJ,
Schranz D. Stent implantation in the ductus arteriosus for
pulmonary blood supply in congenital heart disease. Catheter
Cardiovasc Interv. 2004 Feb; 61(2): 242-52.
7. Holzer R, Balzer D, Cao QL, Lock K, Hijazi ZM; Amplatzer
Muscular Ventricular Septal Defect Investigators. Device
closure of muscular ventricular septal defects using the
Amplatzer muscular ventricular septal defect occluder:
immediate and mid-term results of a U.S. registry. J Am Coll
Cardiol. 2004 Apr 7; 43(7): 1257-63
13. Alwi M, Choo KK, Latiff HA, Kandavello G, Samion H, Mulyadi
MD.Initial results and medium-term follow-up of stent
implantation of patent ductus arteriosus in duct-dependent
pulmonary circulation. J Am Coll Cardiol. 2004 Jul
21;44(2):438-45.
11
Apollo Medicine, Vol.1, September 2004
7. A o oh s i l ht:w wa o o o p a . m/
p l o p a : t / w .p l h s i lc
l
ts p /
l
ts o
T ie: t s / ie. m/o p a A o o
wt rht :t t r o H s i l p l
t
p /w t c
ts
l
Y uu e ht:w wy uu ec m/p l h s i ln i
o tb : t / w . tb . a o o o p a i a
p/
o
o
l
ts d
F c b o : t :w wfc b o . m/h A o o o p a
a e o k ht / w . e o k o T e p l H s i l
p/
a
c
l
ts
Si s ae ht:w wsd s aen t p l _ o p a
l e h r: t / w .i h r.e/ o o H s i l
d
p/
le
A l
ts
L k d : t :w wl k d . m/ mp n /p l -o p a
i e i ht / w . e i c c a y o oh s i l
n n p/
i
n no o
a l
ts
Bo : t :w wl s l e l . /
l ht / w . t a h a hi
g p/
e tk t n